Scale effects on a single-element inverted wing in ground effect

Correia, José Manuel; Roberts, Luke S.; Finnis, Mark; Knowles, K.

doi:10.1017/s0001924000009544

Cited by 13 publications

(44 citation statements)

References 12 publications

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“…It must be assumed that bypass transition has occurred and the boundary layer is turbulent across the entire chord length, given the lack of evidence of either natural or separation-induced transition. The elimination of the bubble depicts similarity to the forced-transition results of Correia et al (15). The fact that the boundary layer is capable of negotiating the adverse pressure gradient without separating (to form the bubble) suggests that it must be turbulent because it cannot have more energy than the undisturbed case given the lower dynamic pressure in which it operates.…”

Section: Figure 4 -Experimental Results For A) Coefficients Of Downfosupporting

confidence: 79%

“…In the undisturbed case a laminar separation bubble, which is the boundary layer transition mechanism for the wing, is noticeable. This phenomenon was discussed previously by Correia et al (15). When operating in the wake, a separation bubble does not form and trailing-edge separation occurs in the centralsection.…”

Section: Figure 4 -Experimental Results For A) Coefficients Of Downfomentioning

confidence: 51%

“…The fact that the boundary layer is capable of negotiating the adverse pressure gradient without separating (to form the bubble) suggests that it must be turbulent because it cannot have more energy than the undisturbed case given the lower dynamic pressure in which it operates. Correia et al (15) also showed that the forcereduction region of the single-element version of the wing configuration tested here was due to an effective de-cambering of the wing due to the separation bubble shrinking. Thus, by the bubble being eliminated the force reduction mechanism has been avoided, hence the lack of the force reduction region in force results shown previously.…”

Section: Figure 4 -Experimental Results For A) Coefficients Of Downfomentioning

confidence: 53%

See 2 more Smart Citations

Aerodynamic characteristics of a monoposto racing car front wing operating in high turbulence conditions

Correia

Roberts

Finnis

et al. 2014

The International Vehicle Aerodynamics Conference

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Section: Figure 4 -Experimental Results For A) Coefficients Of Downfosupporting

confidence: 79%

Section: Figure 4 -Experimental Results For A) Coefficients Of Downfomentioning

confidence: 51%

Section: Figure 4 -Experimental Results For A) Coefficients Of Downfomentioning

confidence: 53%

See 1 more Smart Citation

Aerodynamic characteristics of a monoposto racing car front wing operating in high turbulence conditions

Correia

Roberts

Finnis

et al. 2014

The International Vehicle Aerodynamics Conference

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“…Given that a wing operating in ground effect produces significantly lower pressures and stronger pressure gradients than its out-of-ground-effect counterpart, Reynolds number effects and the importance of transition could be even more important. Although some studies [9][10][11] have cited Reynolds number and transitional effects for ground-effect geometries, there is an overall lack of investigation into the subject. [ [11] Four configurations of three-dimensional double-element wings were examined by Jasinski & Selig [9] through force measurements and a wake study with a 7-hole pressure probe in a fixedground facility.…”

Section: Introductionmentioning

confidence: 99%

“…Although some studies [9][10][11] have cited Reynolds number and transitional effects for ground-effect geometries, there is an overall lack of investigation into the subject. [ [11] Four configurations of three-dimensional double-element wings were examined by Jasinski & Selig [9] through force measurements and a wake study with a 7-hole pressure probe in a fixedground facility. The work included testing the wings at a range of Reynolds numbers in addition to incidence angle and flap position.…”

Section: Introductionmentioning

confidence: 99%

Characteristics of Boundary-Layer Transition and Reynolds-Number Sensitivity of Three-Dimensional Wings of Varying Complexity Operating in Ground Effect

Roberts

Finnis

Knowles

2016

Journal of Fluids Engineering

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The influence of Reynolds number on the aerodynamic characteristics of various wing geometries was investigated through wind-tunnel experimentation. The test models represented racing car front wings of varying complexity: from a simple single-element wing to a highly complex 2009-specification formula-one wing. The aim was to investigate the influence of boundary-layer transition and Reynolds-number dependency of each wing configuration. The single-element wing showed significant Reynolds-number dependency, with up to 320% and 35% difference in downforce and drag, respectively, for a chordwise Reynolds number difference of 0.81 × 105. Across the same test range, the multi-element configuration of the same wing and the F1 wing displayed less than 6% difference in downforce and drag. Surface-flow visualization conducted at various Reynolds numbers and ground clearances showed that the separation bubble that forms on the suction surface of the wing changes in both size and location. As Reynolds number decreased, the bubble moved upstream and increased in size, while reducing ground clearance caused the bubble to move upstream and decrease in size. The fundamental characteristics of boundary layer transition on the front wing of a monoposto racing car have been established.

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Avian whiffling-inspired gaps provide an alternative method for roll control

Sigrest

Inman

2022

Bioinspir. Biomim.

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Some bird species exhibit a flight behavior known as whiffling, in which the bird flies upside-down during landing, predator evasion, or courtship displays. Flying inverted causes the flight feathers to twist, creating gaps in the wing’s trailing edge. It has been suggested that these gaps decrease lift at a potentially lower energy cost, enabling the bird to maneuver and rapidly descend. Thus, avian whiffling has parallels to an uncrewed aerial vehicle (UAV) using spoilers for rapid descent and ailerons for roll control. However, while whiffling has been previously described in the biological literature, it has yet to directly inspire aerodynamic design. In the current research, we investigated if gaps in a wing’s trailing edge, similar to those caused by feather rotation during whiffling, could provide an effective mechanism for UAV control, particularly rapid descent and banking. To address this question, we performed a wind tunnel test of 3D printed wings with a varying amount of trailing edge gaps and compared the lift and rolling moment coefficients generated by the gapped wings to a traditional spoiler and aileron. Next, we used an analytical analysis to estimate the force and work required to actuate gaps, spoiler, and aileron. Our results showed that gapped wings did not reduce lift as much as a spoiler and required more work. However, we found that at high angles of attack, the gapped wings produced rolling moment coefficients equivalent to upwards aileron deflections of up to 32.7° while requiring substantially less actuation force and work. Thus, while the gapped wings did not provide a noticeable benefit over spoilers for rapid descent, a whiffling-inspired control surface could provide an effective alternative to ailerons for roll control. These findings suggest a novel control mechanism that may be advantageous for small fixed-wing UAVs, particularly energy-constrained aircraft.

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Scale effects on a single-element inverted wing in ground effect

Cited by 13 publications

References 12 publications

Aerodynamic characteristics of a monoposto racing car front wing operating in high turbulence conditions

Aerodynamic characteristics of a monoposto racing car front wing operating in high turbulence conditions

Characteristics of Boundary-Layer Transition and Reynolds-Number Sensitivity of Three-Dimensional Wings of Varying Complexity Operating in Ground Effect

Avian whiffling-inspired gaps provide an alternative method for roll control

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